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| 02009cam 2200349za 4500 |
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| 001 | 9.849315 |
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| 003 | CaOODSP |
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| 005 | 20221107153904 |
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| 007 | cr ||||||||||| |
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| 008 | 180102s1985 onca|||fob f000 0 eng d |
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| 040 | |aCaOODSP|beng |
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| 043 | |an-cn-on |
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| 086 | 1 |aEn13-5/86-17E-PDF |
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| 100 | 1 |aStepien, I. |
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| 245 | 12|aA program for solving the unsteady flow equations by implicit four-point method |h[electronic resource] : |bapplication to Niagara River / |cby I. Stepien, D.C.L. Lam and C.R. Murthy, |
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| 260 | |aBurlington, Ont. : |bAquatic Physics and Systems Division, National Water Research Institute, |c1985. |
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| 300 | |a13, [17] p. : |bill. |
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| 490 | 1 |aNWRI contribution ; |v86-17 |
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| 500 | |a"July 1985". |
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| 500 | |aDigitized edition from print [produced by Environment and Climate Change Canada]. |
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| 504 | |aIncludes bibliographical references. |
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| 520 | 3 |a"The implicit four-point method is presented for computing water level elevations and vertically integrated velocities in the open channel [sic]. The theory and FORTRAN program listing of the model are given. Two examples of applications (Vistula River, Poland and Niagara River) have also been included. In particular, the importance of incorporating the flow dynamics in the accurate estimation of contaminant loadings from Niagara River into Lake Ontario is demonstrated. Such a model synthesis approach is essential for the prediction of the transport and fate of the toxic contaminants in the coastal zone"--Abstract. |
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| 692 | 07|2gccst|aModelling |
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| 692 | 07|2gccst|aWater quality |
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| 700 | 1 |aLam, D. C. L. |q(David Chung Lap) |
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| 700 | 1 |aRajasekara Murthy, C.. |
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| 710 | 1 |aCanada. |bEnvironment Canada. |
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| 710 | 2 |aNational Water Research Institute (Canada) |
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| 830 | #0|aNWRI contribution ;|vno. 86-17|w(CaOODSP)9.844121 |
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| 856 | 40|qPDF|s1.70 MB|uhttps://publications.gc.ca/collections/collection_2018/eccc/En13-5-86-17-eng.pdf |
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